highly stereoselective synthesis of cyclopentanes bearing
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Highly stereoselective synthesis of cyclopentanesbearing four stereocentres by a rhodiumcarbene-initiated domino sequenceBrendan T. Parr , Emory UniversityHuw Davies, Emory University
Journal Title: Nature CommunicationsVolume: Volume 5Publisher: Nature Publishing Group: Nature Communications | 2014-08-01Type of Work: Article | Final Publisher PDFPublisher DOI: 10.1038/ncomms5455Permanent URL: https://pid.emory.edu/ark:/25593/pg1k3
Final published version: http://dx.doi.org/10.1038/ncomms5455
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ARTICLE
Received 21 Oct 2013 | Accepted 19 Jun 2014 | Published 1 Aug 2014
Highly stereoselective synthesis of cyclopentanesbearing four stereocentres by a rhodiumcarbene-initiated domino sequenceBrendan T. Parr1 & Huw M.L. Davies1
Stereoselective synthesis of a cyclopentane nucleus by convergent annulation constitutes a
significant challenge for synthetic chemists. Although a number of biologically relevant
cyclopentane natural products are known, more often than not, the cyclopentane core is
assembled in a stepwise manner because of the lack of efficient annulation strategies. Here
we report the rhodium-catalysed reactions of vinyldiazoacetates with (E)-1,3-disubstituted
2-butenols generate cyclopentanes, containing four new stereogenic centres with very high
levels of stereoselectivity (99% ee, 497: 3 dr). The reaction proceeds by a carbene-initiated
domino sequence consisting of five distinct steps: rhodium-bound oxonium ylide formation,
[2,3]-sigmatropic rearrangement, oxy-Cope rearrangement, enol—keto tautomerization and
finally an intramolecular carbonyl ene reaction. A systematic study is presented detailing
how to control chirality transfer in each of the four stereo-defining steps of the cascade,
consummating in the development of a highly stereoselective process.
DOI: 10.1038/ncomms5455
1 Department of Chemistry, Emory University, 1515 Dickey Drive, Atlanta, Georgia 30322, USA. Correspondence and requests for materials should beaddressed to H.M.L.D. (email: hmdavie@emory.edu).
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Construction of cyclopentanes constitutes an area ofsignificant interest in the organic community1–3, asevidenced by numerous campaigns towards land-
mark natural products, including the prostaglandins4–16,jatrophanes17–25 and pactamycin26,27. Synthetic cyclopentanesare a central motif common to prostaglandin antagonistantiglaucoma agents28–32. Indeed, the convergent, asymmetricsynthesis of a cyclopentane nucleus bearing multiple chiralcentres presents a distinct challenge for modern syntheticchemists. A general difficulty for a [3þ 2]-cycloadditionapproach is developing a mild protocol to render a transientcarbon dipole.
One of the classic strategies for chiral cyclopentene synthesisinvolves stereoselective cyclopropanation of a 1,3-diene, followedby vinylcyclopropane rearrangement33–36. Contemporary effortshave involved the coupling of a suitably activated olefinic motifwith an all carbon (1,3) dipole bound to a chiral metal centre via aformal [3þ 2]-cycloaddition37–40. A significant advancementhas been the enantioselective cycloaddition of palladatedtrimethylenemethane with electron-deficient alkenes developedby Trost et al.41–43 Alternatively, Fu et al.44,45 andZhang et al.46 have disclosed enantioselective variants of the Lucycloaddition47–53 implementing chiral phosphine catalysts.Although a number of methods are available, the development
MeO2COH
R R1
Me
HO R1
Me
Me
Rh2(R-DOSP)4then Sc(OTf)3/D
high dr, moderate ee
N2
MeO2C
R
MeO2C OH
R R2
R1
HO R2
R1
Me
Rh2(R-DOSP)4 then DNo Sc(OTf)3
high dr, high ee
N2
MeO2C
R
+
+
1 32
1 4 5
bThis work
aKnown
Figure 1 | Evolution of a Convergent Cyclopentane Synthesis. (a) One-pot synthesis of a cyclopentane (3) from a vinyldiazoacetate (1) and racemic allyl
alcohol (2) in modest enantioselectivity via a rhodium-initiated cascade. (b) A second-generation cyclopentane (5) synthesis from analogous starting
materials in high stereoselectivity.
OH Me
PhCO2Me
OH
MePh
OMeO2C
MePh
OHMeO2C
Me
[3,3]/enol-keto
82% ee>30:1 dr
Carbonyl ene
82% ee>30:1 dr
N2
MeO2C
Ph
HO
Me
O
CO2MeRh
Ph
+
Rh-boundoxonium ylide
[2,3] 98% ee
6 7Me
H
Ph
Me
MeO2C
CO2Me
O
Ph
CH2
H
Me
Me
I
II
III
89
10
Figure 2 | Mechanism of cyclopentane synthesis. Mechanism of the one-pot domino sequence for the synthesis of a cyclopentane (10) from a
diazoacetate (6) and a racemic allyl alcohol (7).
ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5455
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of complementary strategies for the rapid construction ofcomplex cyclopentanes is nonetheless desirable.
In this article, we describe a convergent, stereoselectivesynthesis of cyclopentanes with four stereogenic centres froman annulation cascade involving vinyldiazoacetates and chiralallyl alcohols. Moreover, a detailed analysis to account forcorrelations between starting material architecture and reactionefficacy is described.
ResultsFirst-generation synthesis. In a 2011 report, we described ourinitial attempts to synthesize complex cyclopentanes 3 by meansof a cascade sequence54. The strategy involved the coupling ofracemic 3,3-dimethyl allyl alcohols (2) and donor/acceptor-substituted Rh(II) carbenes55,56 derived from vinyldiazoacetates 1
in the presence of the dual-catalyst system, Rh2(DOSP)4 andSc(OTf)3, shown in Fig. 1a. Implementing 1 Mol % of chiral Rhcatalyst enabled a high-yielding preparation of a range ofcyclopentanes 3, containing four stereogenic centres, as singlediastereomers. Although we were pleased with the generalefficacy with which a high degree of structural complexitywas introduced from readily available building blocks, thereaction was characterized by a significant shortcoming: theenantioselectivity for the synthesis of 3 was variable (68–92% ee).In this paper we describe our diagnosis of the stereochemicallimitations in our initial study, and the logical design of astereo-controlled cyclopentane 5 synthesis, as illustrated inFig. 1b.
Our previous synthesis of cyclopentane 3 involved fourdiscrete, stereo-defining reactions, as illustrated for the specificexample in Fig. 2 (ref. 52). The steps include: Rh-bound
MeO2C
MeO2C
Ph
O
MeO2C
MeO2C
O
Ph
HOCO2Me
Ph
MeO2C OH
Ph
PhPh
IV′
a b
c
MeO2CCO2Me
OHHO
ΔG = 1.25 kcal mol–1 ΔG = 0.55 kcal mol–1
OH
9′
ent-9′
10
ent-10
HO
IV
91%
9%
Favorable configuration Unfavorable configuration
Figure 3 | Stereoelectronic considerations for an oxy-Cope rearrangement. Cyclohexane A values for carbomethoxy- (a) and hydroxy (b) -substituted
cyclohexanes. (c) Manifestation of stereoelectronic effects in the competition between two chair-like transition states (IV and IV0).
R N2
CO2Me
R1
R2
R3
OH
R3
ROH
R2
R1
CO2MeRh2(DOSP)4
+
R N2
CO2Me
R1
R2
R3
OH
R3
ROH
R2
R1
CO2MeRh2(R-DOSP)4
+R
R3 OH
MeO2CR2
R1
a
b
1 11 12
1 (S)-11 (S,R )-12 (S,R )-12′
All stereoisomersprepared
12 – >20:1 dr,>99% ee
Catalyst controlled stereocenter
Alcohol controlled stereocenter
Favorable configuration
Figure 4 | Rationale for improved chirality transfer during an oxy-Cope rearrangement. (a) The tandem-ylide formation/[2,3]-sigmatropic
rearrangement between a diazoacetate (1) and allyl alcohol (S)-11 (2) to generate a 3-hydroxy-1,5-hexadiene (12) bearing vicinal stereocentres
and (b) application toward stabilization of a chair-like transition state.
NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5455 ARTICLE
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oxonium ylide formation (6 and 7-I), [2,3]-sigmatropic re-arrangement (I-8)55 oxy-Cope rearrangement (8-II-9) andintramolecular carbonyl ene reaction (9-III-10). Although themetal-bound ylide intermediate I is neither isolated nor observed
in the tandem reaction, its intermediacy is well precedented in theliterature54–60. From previous studies on the tandem ylideformation/[2,3]-sigmatropic rearrangement61 as well as controlstudies52 we have analysed the stereochemically relevant steps in
Control - Mismatch
One-Pot - Match
One-Pot - Mismatch
HO Me MePh
Heptanes, Δ
82% yield88:12 dr, 39% ee
Rh2(R-DOSP)4heptanes, 0-120 °C
71% yield88:12 dr, 91% ee
MeN2
MeO2C
Ph
Rh2(S-DOSP)4heptanes, 0-120 °C
52% yield88:12 dr, 40% ee
+
Control - Match
**
MePh
Heptanes, Δ
99% yield88:12 dr, >99% ee
OH
CO2Me
Me
Ph
Ph Me
MeMeO2C O
H
Me
Heptanes, Δ
31% yield >30:1 dr, >99% ee
Control - Match
OH
CO2Me
Me
Ph
H
Me
CO2Me
OH
Me
Ph
H
Me MePh
HO Me MePh
MeN2
MeO2C
Ph
+
13
13 15
epi-13
14
15
6 16 15
6 16 15
OHMeO2C
OHMeO2C
OHMeO2C
OHMeO2C
N2
CO2MePh
6
OH
MeMe
16
+
Rh2(R-DOSP)4
si approach
RhCO2Me
OH
Me HMe
Ph
RhCO2Me
OMe
H MeH
Ph
V
VI
Ph
Me
Ph
Me
OH
CO2Me
Me
H
OH
CO2Me
H
Me
13
epi-13
[2,3]
91%
[2,3]
9%H
H
f
a
b
c
d
e
Figure 5 | Control studies relevant to the synthesis of cyclopentane 15. (a) Chirality transfer control for the oxy-Cope rearrangement. Matched (b)
and mismatched (c) tandem oxy-Cope rearrangement hetero-ene reactions of stereoisomerically pure 3-hydroxy-1,3-hexadienes (13 and epi-13,
respectively). Matched (d) and mismatched (e) one-pot cyclopentane (15) syntheses. (f) Justification for high, but imperfect, diastereocontrol
during the rhodium-catalysed ylide formation/[2,3]-sigmatropic rearrangement.
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the cascade sequence. We observed excellent enantiocontrolduring the rhodium-catalysed process for generating the3-hydroxy-1,5-hexadiene 8 (98% ee). Intermediate 8 thenunderwent a [3,3]-sigmatropic rearrangement through a chair-like transition state (II). Upon a subsequent enol—ketotautomerization, the product 9, containing two newstereocentres, was furnished. The oxy-Cope rearrangementafforded a single diastereomer of ketoester 9, an observationconsistent with chair-like transition states being solelyoperative52,61–64. Isolation and chiral HPLC analysis of 9,however, indicated partial racemization during the course ofthis step of the cascade sequence. The terminating sequenceof the cascade—intramolecular carbonyl ene reaction viaIII—proceeded smoothly to furnish cyclopentane 10 as a singlediastereomer. No further degradation in enantiopurity wasobserved during the ene reaction. These studies identify theorigins of the moderate overall enantioinduction: modest chiralitytransfer during the oxy-Cope rearrangement.
Stereochemical limitations. A rationale for the erosion inenantiopurity observed during the course of the oxy-Cope rear-rangement is provided schematically in Fig. 3. On the basis ofcyclohexane A values, the equatorial versus axial positioningof carbomethoxy (Fig. 3a) and hydroxy (Fig. 3b) substituentswould be favoured by 1.25 and 0.55 kcal mol� 1, respectively65.Equilibration between two possible chair-like intermediates forthe [3,3]-sigmatropic rearrangement, shown in Fig. 3c, is morecomplicated. Both geminal disubstitution66 and pseudoanomericstabilization of the allyl hydroxy group67 influence the
equilibrium between IV and IV0. On the basis of the A-valuesof the individual substituents and the psuedoanomericstabilization-afforded IV, we can rationalize the modestpreference for that pathway. Nevertheless, rearrangement viathe energetically less favourable intermediate IV0 would also befeasible. Upon undergoing the Cope rearrangement, two of thestereogenic centres found in the cyclopentane (10), C(3) andC(4), have been installed. As can be seen from comparison of9 and ent-9, the competing chair-like transition states giverise to enantiomeric intermediates. Thus, enantiomers of thecyclopentane, 10 and ent-10, arise from the competition betweenIV and IV0. The 82% ee observed for the cyclopentane 10synthesis is because of approximately a ten-to-one preference forIV over IV0.
Rationale for second-generation synthesis. Having analysed thereaction responsible for partial racemization in the cascadesequence, we honed our efforts towards a general solution to theproblematic step. On the basis of the hypothesis that competingchair-like transition states during the oxy-Cope rearrangementwere the source of poor chirality transfer, we designed newsystems that would suppress this equilibration and stronglyfavour one chair-like transition state over the other.
In a recent article, we described the tandem ylide formation/[2,3]-sigmatropic rearrangement of readily available chiral allylalcohols with donor/acceptor-substituted rhodium carbenes75.For alcohols with variable substitution at C(3) (Fig. 4a, 11,R1aR2), rearrangement products bearing vicinal stereocentres(12) were generated with very high enantiocontrol (499% ee)
CO2Me
OPh
Me
CO2Me
CH2
H
H
O
Ph
Me
CH2
HH
Ph
Me
Me
CO2Me
O
VII
VIII
Ph
Ph
Me
Me
14
15
epi-15
ene
88%
ene
12%
O
PhMe
H
Ph
Me
CO2Me
O
IXPh
Ph
Me
Me
21
20
(Z )-20
ene
ene
R
HH
MeO O
O
PhMe
H
X
H
RH
MeO O
R
R
R
OHMeO2C
OHMeO2C
OHMeO2C
CO2MeHO
a
b
Figure 6 | Rationale for diastereoselectivities in the hetero-ene reaction. (a) Envelope-like transition states VII and VIII for the formation of 15 and epi-
15, respectively. (b) Rotational isomers of an ene transition state IX and X for the formation of 20 and (Z)-20, respectively.
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and moderately high diastereocontrol (12�420: 1). Specifically,the rhodium catalyst dictated the configuration of the hydro-xyester stereocentre (green sphere), while the allyl alcoholcontrolled the configuration of the second chiral centre (bluesphere). Thus, we demonstrated that the proper combination ofeach enantiomer of Rh2(DOSP)4 and allyl alcohol enabled thesynthesis of all four diastereomers of 12. We envisioned that the[2,3]-sigmatropic rearrangement to generate a product withadjacent stereocentres could provide the necessary solution tochirality transfer during the problematic oxy-Cope rearrange-ment, as shown in Fig. 3b. Specifically, the proper configurationof a 3-hydroxy-1,5-hexadiene (12) would enable a single chair-like intermediate, wherein both chiral centres would orientcooperatively (120), with the substituents having larger A-valuespositioned equatorially (R14R2). Herein, we report the synthesis-based exploration of that hypothesis and the development of ahighly stereoselective cyclopentane synthesis.
DiscussionOur investigations into an improved cyclopentane synthesisbegan with a series of control reactions. First, the diastereo- andenantiomerically pure 3-hydroxy-1,5-hexadiene 13 (ref. 75) washeated in a sealed tube for 12 h. Direct purification using flashchromatography afforded a small amount of the ketoester 14 as asingle stereoisomer (Fig. 5a). The modest isolated yield of 14 isbecause the crude reaction mixture contains a mixture of startingmaterial (13), ketoester (14) and cyclopentane (15). Prolongedheating of 13 furnished the desired cyclopentane 15 in excellentyield and with no loss in the level of enantioselectivity, as shownin Fig. 5b. The product 15 was, however, formed as an 88: 12mixture of diastereomers. Having established that the keto ester
14 is formed as a single diastereomer, it appears that the carbonylene reaction to form 15 is no longer highly diastereoselectivewith these substrates. Comparison with literature precedent22 andour own analyses of the nuclear Overhauser effects(Supplementary Figs 1 and 2) in 15 are indicative of inversionin the configuration at the C(1)- and C(2) stereocentres in theminor product.
In order for the Cope rearrangement to proceed with highenantiocontrol, the two chiral centres of the hexadiene mustcooperatively reinforce a single chair-like transition state, asillustrated in Fig. 5a and b. In the negative control reaction withthe epimeric material epi-13, the two chiral centres are orientatedcompetitively, such that only the carbomethoxy or the methylgroup can occupy an equatorial position in the two availablechair-like forms (Fig. 5c). The reaction with epi-13 demonstratedthe detrimental effect on enantiocontrol, as the cyclopentane 15was obtained with considerable racemization (39% ee) because ofcompeting chair-like transition states. The identical diastereo-meric ratio of product cyclopentanes observed for the matchedand mismatched reactions (Fig. 5b,c) was again consistent with aproblematic carbonyl ene reaction. These studies revealed that asecond stereocentre could be manipulated for enantiocontrol inthe oxy-Cope rearrangement but generated new problems withregard to the diastereoselectivity of the ene reaction.
The control studies revealed that the rearrangement of thehexadienol 13 to cyclopentanol 15 could be achieved underthermal conditions without the use of scandium triflate as a Lewisacid catalyst. Therefore, modified conditions were developed forthe one-pot process. Rh2(R-DOSP)4-catalysed reaction of vinyl-diazoacetate 6 with the allyl alcohol 16 followed by heating of thecrude mixture for 24 h afforded the desired product in a gratifying71% yield (Fig. 5d). While the diastereomeric ratio for the one-pot process was identical to that for the control reaction shown inFig. 5b, an unanticipated decrease in the level of enantioselectivitywas observed in the matched reaction to form 15. The level ofenantioselectivity was 91% ee, which is an improvement over ourprevious studies52, but still not ideal. The one-pot mismatchedreaction (Fig. 5e), conducted by implementing the oppositeenantiomer of catalyst [Rh2(S-DOSP)4], resulted in an overall lessefficacious synthesis of 15, as expected. The enantioselectivity ofthe transformation was consistent with that observed during thetandem oxy-Cope/ene study (Fig. 5c).
The discrepancy in enantioselectivity for the cyclopentaneformation in the Cope/ene sequence (Fig. 5b) versus the completeone-pot sequence (Fig. 5d) is attributed to a slight diasteromeric‘leakage’ occurring during the [2,3]-sigmatropic rearrangement(Fig. 5f). In our previous study, we rationalized the driving forcefor diastereoselection in the ylide formation/[2,3] rearrangementto be minimization of A1,3-strain in the ylide intermediate. Whilethe strain-minimized transition state V is preferred, for thepentenol 16, the epimeric product (epi-13) is also formed(13: epi-13 ratio, B11: 1) because the strain formed between asyn-pentane methyl and hydrogen group in transition state VI isnot severe. According to the control study described in Fig. 5c,the minor [2,3]-product epi-13 will contribute to formation of theenantiomer of 15.
Another challenge with the second-generation substrates wasthe formation of diastereomers during the ene reactions. Themodest level of diastereoselectivity in this step can be rationalizedby a transition state analysis. Placing the ene and enophilecomponents of 14 in a syn orientation to allow for requisiteorbital overlap renders two feasible transition states (Fig. 6a, VIIand VIII). As with the [2,3]-sigmatropic rearrangement, mini-mization of A1,3-strain is a governing factor in the carbonyl enereaction. Since the ene consists of a trans-1,2-disubstitutedalkene, the origins of any A1,3-strain are from interaction between
Table 1 | *Variations in carbinol substitution.
N2
MeO2C
Ph
Me
RHO
OHMeO2C
RPh
Rh2(R-DOSP)42 equiv CaCl2
heptanes, 0–125 °C+
6 17a–d 18a–d
entry comp′d product yield, %† dr‡ ee, %§
1
2
3
4
a
b
c
d
65
71||
70
55||
89:11
88:12
92:8
93:7
92
92
92
93
OHMeO2C
EtPh
OHMeO2C
n-HexPh
OHMeO2C
c-HexPh
OHMeO2C
Ph OBn
HPLC, high¼ performance liquid chromatography.*Reaction conducted with 17 (0.50 mmol, 1.0 equiv), 6 (0.60 mmol, 1.2 equiv) and Rh2(R-DOSP)4 (0.0005 mmol, 0.1 mol%), unless otherwise indicated.wIsolated yield of the major diastereomer.zDetermined using 1H NMR analysis of the crude reaction residue.yDetermined using HPLC analysis on a chiral stationary phase.||Yield of the reaction with 0.5 mol% Rh2(R-DOSP)4.
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the vinylic proton and the pseudoequatorial allylic methyl group.Interestingly, a similar strain interaction occurring during the[2,3]-rearrangement ene reactions produces similar levels ofdiastereoselectivity. Thus, while diastereomer 15 arising fromcyclization via VII is preferred, some of the product epi-15originating from the slightly more strained transition state VIIIare also formed.
These studies verified both the feasibility of generatingcyclopentanes in high levels of enantioselectivity via a one-potprocess and the necessity of matching catalyst and alcohol chirality.We decided to explore whether the trend we observed with the allylalcohol 16 would be extended to other secondary allyl alcohols.The diazoacetate 6 was chosen as the standard carbene precursoras it has been studied extensively in tandem ylide formation/[2,3]-sigmatropic rearrangement chemistry52,55,68,69. We found thatincorporating superstoichiometric quantities of calcium chlorideenabled a 10-fold reduction in the loading of dirhodiumtetracarboxylate catalyst without any loss in asymmetricinduction and, therefore, it was incorporated as part of thestandard reaction conditions. We believe CaCl2 helps to minimizecompetitive coordination of the alcohol to the vacant axial site ofthe dirhodium tetracarboxylate catalyst, a process that impedesdenitrogenative decomposition of the diazoacetate (seeSupplementary Table 1).
The first series of alcohols (17a–d) examined, similar to thosein our previous cyclopentane synthesis52, varied in carbinolsubstitution (Table 1). We envisioned that an increase in stericbulk at the carbinol (compared with 16) could enhance thediastereoselectivity of the [2,3]-sigmatropic rearrangement and,therefore, the overall enantioselectivity of the cyclopentanesynthesis. Increasing the length of the alkyl chain (entries 1–2,17a–b) had no effect on the stereocontrol of the reaction.Introduction of more encumbered secondary carbon orbenzylether substituents (entries 3–4, 17c–d, respectively)adjacent to the carbinol provided comparable yields and levelsof enantioselectivity with a slight improvement in the levels ofdiastereoselectivity.
We then explored the effect of increasing the bulk of thealcohol C(3) substitituent, which participates in A1,3 interactionsduring the [2,3]-sigmatropic rearrangement. A modest improve-ment in enantioselectivity was observed when a C(3)-Mesubstituent (Fig. 5d, 16) was replaced by an isopropyl moiety(Table 2, entry 1, 19a, R1¼R2¼Me). The diastereoselectivity,however, was similar to that observed for the previous class ofallyl alcohols. For alcohols where R1 and R2 were not equivalent,an added element of complexity in the form of olefin geometrywas introduced (entries 2–4, 19b–d). The yields and levels ofstereoselectivity were fairly consistent throughout the group;
Table 2 | *Variations in allylic substitution.
entry comp′d product yield, %† dr‡ ee, %§
Me
MeO2C
Ph
OH
Me
MeO2C
Ph
OH
Me
MeO2C
Ph
OH
Me
MeO2C
Et
OH
1
2
3
4
a
b
c
d
71 91:9 95
65 85:15 96
67 90:10 94
R Me
OHMeO2C
Rh2(R-DOSP)42 equiv CaCl2
heptanes, 0–125 °C
HO Me
19a–d 20a–d
N2
MeO2C
Ph
+
6
80|| 90:10 95
R1R2R1R2
Me
E:Z ‡
–
2.2:1
3.4:1
7.3:1
Me
C4H9
Ph
Me
HPLC, high¼ performance liquid chromatography.*Reaction conducted with 19 (0.50 mmol, 1.0 equiv), 6 (0.60 mmol, 1.2 equiv) and Rh2(RDOSP) 4 (0.0005 mmol, 0.1 mol%), unless otherwise indicated.wIsolated yield of the major diastereomer.zDetermined using 1H NMR analysis of the crude reaction residue.yDetermined using HPLC analysis on a chiral stationary phase.||Yield of the reaction with 0.5 mol % Rh2(RDOSP)4.
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however, (E)-selective alkene formation was correlated with thesize of R1. Specifically, linear alkyl chains (19b–c) providedcomparable ratios of E- and Z diastereomers (entries 2–3, ca. 3:1,E:Z), but a benzyl substituent afforded cyclopentane (E)-20d ingreater than 7:1 E/Z mixture.
The preference for the formation of the E-isomers of 20 isconsistent with the transition state model presented for the enereaction as illustrated in Fig. 6b. Minimization of A1,3 interactionsdictates the major reaction pathway. By rotating the methylenecarbon of the ene fragment (Fig. 6b, IX versus X), the allylicR-group would be positioned either trans or cis to the vinylicproton. The former, less strained intermediate would giverise to the (E)-cyclopentane 20, and the latter to the lesspreferred (Z)-20.
On the basis of the experimental observations and thetransition state analysis, it became apparent that a highlystereoselective entry to the cyclopentanes would require effectivecontrol of chair transition states in the oxy-Cope rearrangementand maximization of the A1,3-strain control in the [2,3]-sigmatropic rearrangement and the ene reaction. Therefore, weexamined a series of alcohols 23 bearing geminal disubstitution atthe C(3) position (Table 3). One of the substituents was methyl tomaximize chair selectivity in the oxy-Cope rearrangement andto minimize the formation of isomers in the ene reaction.
The desired chiral alcohols (23) were readily prepared fromcommercially available enals or by means of carbometallation68,70
of the requisite alkynes and trapping with acetaldehyde. Theresults of the cyclopentane formation from 23 are described inTable 3. In each case the reaction proceeds in very high yield(85–89%) and with excellent levels of stereoselectivity. Thecyclopentanes 24 were formed in 430:1 dr and in 99% ee. Thereaction is likely to be applicable to a range of vinyldiazoacetatesas the alkyl-substituted vinyldiazoacetate (22, R¼ Et) wassimilarly effective in the net transformation. The absoluteconfiguration of cyclopentane 24a was verified by X-raycrystallographic analysis and this assignment was applied tothe other products by analogy. Moreover, the absoluteconfiguration was consistent with the assignments in our earlierstudies58.
Although the cyclopentane bearing a quaternary hydroxycar-bonyl stereocentre is a common structural motif amongnumerous polyterpenoid natural products (for example, jatro-phane diterpenoids), we sought to demonstrate the ease withwhich the products could be converted to the correspondingcyclopentanones. To this end, reduction of the cyclopentanecarboxylate to the 1,2-diol was affected by lithium borohydride.Quenching with pH 7.0 buffer followed by direct treatment of thecrude reaction mixture with excess sodium periodate furnished
Table 3 | *Variations in vinylic substitution.
entry comp′d product yield, %† dr‡ee, %§
Me
MeO2C
Ph
OH
Me
MeO2C
Ph
OH
Ph
Me
Me
Me
MeO2C
Ph
OH
Ph
Me
MeO2C
Et
OH
Ph
1
2
3
4
a
b
c
d
87 >97:3 99
85 >97:3 99
86 >97:3 99
R Me
OHMeO2CRh2(R-DOSP)42 equiv CaCl2
heptanes, 0–125 °C
HO Me
23a–c 24a–d
R1
N2
MeO2C
R
+
6 (R=Ph)22 (R=Et)
R1
Me
89 >97:3 99
LiBH4 then NaIO4THF, 0–60 °C
67% yield (from 24a)>97:3 dr, 99% ee
O
Ph Me
Ph
25
HPLC, high¼ performance liquid chromatography.*Reaction conducted with 23 (0.50 mmol, 1.0 equiv), 6 (0.60 mmol, 1.2 equiv) or 22 (1.0 mmol, 2.0 equiv) and Rh2(R-DOSP)4 (0.0005 mmol, 0.1 mol%), unless otherwise indicated.wIsolated yield of the major diastereomer.zDetermined using 1H NMR analysis of the crude reaction residue.yDetermined using HPLC analysis on a chiral stationary phase.
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the cyclopentanone 25 in good yield with no observableepimerization of the a-stereocentre (Table 3).
A detailed summary and analysis of the processes involved forstereoselective synthesis of (R,R,R,S)-28 from alcohols such as 23is presented in Fig. 7. The four discrete steps involved are thefollowing: oxonium ylide formation (Step 1), [2,3]-sigmatropicrearrangement (Step 2), oxy-Cope rearrangement (Step 3) andcarbonyl ene reaction (Step 4).
The reaction sequence commences with nucleophilic additionof 23 to the rhodium-bound carbene intermediate derived fromdiazoacetate 6. A high degree of enantiocontrol is exerted by therhodium catalyst, dictating si approach to the metallocar-bene55,68,69. Thererfore, the analysis shown in Fig. 7 is limitedto compounds generated from the si face attack. Due to the severeA1,3-strain that develops between the allylic methyl substituentsin TS2,31, the reaction proceeds selectively through TS2,32,
N2
CO2MePh
6
OH
Me R
Me
23
+
Rh2(R-DOSP)4si approach
PhCO2Me
OH
MeR
Me
TS2,32 (S,S)-26
RhCO2Me
OHH
R MeMe
PhPhCO2Me
OH
RMe
Me
TS2,3I(S,S )-26
TS3,3-3 TS3,3-4TS3,3-2TS3,3-1
CO2Me
OPh
Me
CO2Me
R
CH2
H
PhMe
O
CO2Me
O
Ph
Me
R
CH2
H
OHMeO2C
Ph Me
CO2MeHO
Ph Me
OHMeO2C
Ph Me
CO2Me
Ph Me
R
R
R
R
(R,R,R,S)-28
(S,S,R,S)-28
(S,S,S,R)-28
(R,R,S,R)-28
(R,R,E)-27
(S,S,Z)-27
CO2Me
O
Ph
Me
CH2
HR
PhMe
CO2Me
PhMe O
CO2Me
H2C
PhMe
O
CO2Me
H2CR
H
H
(S,S,E)-27
(R,R,Z)-27
Metallocarbene-Ylideformation
[2,3]-Sigmatropicrearrangement
[3,3]-oxy Coperearrangement
Hetero-Enereaction
or
Step 1
Step 2A Step 2B
RCH2
H
PhMe
CO2Me
O
CH2R
H
Step 3A
Step 3B Step 3C
Step 3D
O
CH2
H
R
R
Step 4E
Step 4F
Step 4G
Step 4H
Ste
p 4A
Ste
p 4B
Ste
p 4C
Ste
p 4D
Major pathway
Minor pathway(for alcohols 16, 17 & 19)
Unobserved pathway
Ph
Me CO2MePh
Me
O
CO2Me
PhMe R
Me
O
CO2Me
PhMe Me
R
O
CO2Me
Ph
Me OH
Me
R
OR
Me
MeO2C Me
R PhMe Me
R
OH
CO2Me
Ph
Me
MeO2C
OH
R
MePhMe R
Me
OH
CO2Me
RhCO2Me
HOMe
Me RH
Ph
(S ) Chiral center
(R ) Chiral centerFavored orientation
Disfavored orientation
TSe-1
TSe-2
TSe-3
TSe-4
TSe-5
TSe-6
TSe-7
TSe-8
Operative pathw
ay when R
= M
e (ref. 58)
HO
a
b
c
d
Figure 7 | Plausible reaction pathways in the cyclopentane synthesis.
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affording the hexadiene diastereomer (S,R)-26. Rendering thereaction intermediate into a chair-like transition state producesTS3,33, where the bulkiest substituents (CO2Me and R) areoccupying equatorial positions. Proceeding through an oxy-Coperearrangement with tandem enol—keto tautomerization providesthe a-ketoester (S,S,E)-27. As with the [2,3]-sigmatropicrearrangement, the driving force for diastereoselectivity in thecarbonyl ene reaction is minimization of A1,3 interactions. Thus,the transition state where the allylic methyl groups are orientedon opposite faces of the ensuing cyclopentane (TSe-5) is thedominant pathway. The result is the formation of the observedstereoisomer of the cyclopentane (R,R,R,S)-28.
In our previous study where the [2,3]-sigmatropic rearrange-ment products lacked a second stereocentre (26, R¼Me), the 1,5-hexadiene is forged with excellent enantiocontrol. Nonetheless,during the oxy-Cope rearrangement TS3,3-4 becomes a viable,albeit minor, reaction pathway to give rise to (R,R)-27 (R¼Me).Since the allylic (ene) portion of the molecule is trisubstitued, it isstill able to exploit a high degree of A1,3-strain, resulting indramatic preference for carbonyl ene reaction through TSe8 ratherthan TSe7. As a result, the enantiomeric cyclopentane (S,S,S,R)-28is formed competitively, resulting in moderate enantiomeric excessfor the overall synthesis. When the allylic alcohol was not 3,3-disubstituted (for example, 16, 17, and 19), TS2,31 becomes viablein the 2,3-sigmatropic rearrangement leading to the formation ofsome of the enantiomeric products (S,S,S,R)-28. In addition, TSe2becomes viable in the ene reaction leading to the formation ofsome of the diastereomeric products (S,S,R,S)-28.
Thus, a domino reaction of rhodium vinylcarbenes andenantiopure allyl alcohols provides a convergent strategy for thesynthesis of cyclopentane carboxylates. Employing just 0.1 mol %of chiral catalyst, three new bonds are formed while installingfour contiguous stereocentres in high yield with excellentdiastereo- and enantioselectivity. A range of functional groupscan be introduced at three of the stereogenic centres by variationsin the allyl alcohol and vinyldiazoacetate. The fourth hydro-xyester stereocentre is readily manipulated to generate complexcyclopentanones via a one-pot reduction/oxidation procedure.Each discrete step in the reaction sequence involves distinctchirality-transfer events, which can be manipulated by appro-priate substitution of the alcohol and ensuing intermediates. Adetailed understanding of the stereochemical processes involvedin the cascade has been developed, allowing for exceptionalcontrol over each stereochemical transfer. The low catalystloadings, readily available starting materials and in-depth under-standing of the mechanistic details make this an attractivemethod for accessing substituted cyclopentanes.
MethodsGeneral considerations. All reactions were conducted in oven-dried glasswareunder an inert atmosphere of dry argon. All chemicals were purchased from eitherSigma-Aldrich, TCI America, Acros or Alfa-Aesar and were used as received.Pentane, hexanes, tetrahydrofuran and diethyl ether were obtained from aGrubbs-type solvent purification system. Heptanes were purchased from MacronFine Chemicals and were used as received. Calcium chloride was dried at 200 �Cunder vacuum for 12 h and stored in a dessicator. 1H NMR spectra were recordedat either 400 MHz on an INOVA-400 spectrometer or at 600 MHz on an INOVA-600 spectrometer. 13C NMR spectra were recorded at 100 MHz on an INOVA-400spectrometer. NMR spectra were recorded in deuterated chloroform (CDCl3)solutions, with residual chloroform (d 7.27 p.p.m. for 1H NMR and d 77.23 p.p.m.for 13C NMR) or tetramethylsilane (d 0.00 p.p.m. for 1H NMR) taken as theinternal standard, and were reported in p.p.m. Abbreviations for signal couplingare as follows: s, singlet; d, doublet; t, triplet; q, quartet; m, multiplet. Couplingconstants were taken from the spectra directly and are uncorrected. IR spectra werecollected on a Nicolet iS10 FT-IR spectrometer as neat films. Mass spectrumdeterminations were carried out on a Thermo Finnigan LTQ-FTMS spectrometerwith electrospray or atmospheric pressure chemical ionization. Optical rotationswere measured on JASCO P-2000 polarimeter. Gas chromatography (GC) analysiswas performed on an Agilent 7890A; column conditions: 30 �C for 1 min, then
increasing to 180 �C at a rate of 5 �C min� 1, then 180 �C for 5 min. Analytical thinlayer chromatography was performed on silica gel plates using UV. For details ofchromatography and previously reported syntheses of substrates 2, Rh2(S-DOSP)4
and Rh2(R-DOSP)4, 16, 17b–d, 19a and c, 23b, 17a, 19b, 19d, and 23a, seeSupplementary Methods. For 1H and 13C NMR data see Supplementary Figs 3–34.For HPLC traces, see Supplementary Figs 35–47. For an ORTEP diagram ofcompound 24a, see Supplementary Fig. 48.
General procedure. A 35-ml pressure tube fitted with a rubber septum wasevacuated and backfilled with dry Ar (3� ). The reaction vessel was charged withRh2(R-DOSP)4 (0.9 mg, 0.005 mmol, 0.1 mol %) and anhydrous CaCl2 (111 mg,1.0 mmol, 2.0 equiv) before adding a heptane solution (1.0 ml) of 16 (43 mg,0.50 mmol, 1.0 equiv). The suspension was cooled to 0 �C in an ice bath. A heptanesolution (5 ml) of 6 (121 mg, 0.60 mmol, 1.2 equiv) was added dropwise over 0.5 haccompanied by vigorous stirring. The reaction was further stirred at 0 �C for 2 h,before removing the ice bath and allowing to warm to ambient temperature.The rubber septum was removed and the vessel was sealed with a Teflon screwcap.The sealed tube was immersed in an oil bath preheated to 125 �C. After 48 h,the reaction was cooled to ambient temperature and the suspension was filteredthrough a fritted glass funnel, washing the filter cake with pentane (3� 10 ml), andthe filtrate was concentrated in vacuo. Column chromatography (SiO2, pentane/diethyl ether, 10:1) afforded a single diastereomer of the pure product 15 (92 mg,71% yield). For additional procedures see Supplementary Methods.
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AcknowledgementsThis research was supported by the National Institutes of Health (GM099142). We thankDr John Bacsa (Emory University) for the X-ray crystallographic analysis.
NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5455 ARTICLE
NATURE COMMUNICATIONS | 5:4455 | DOI: 10.1038/ncomms5455 | www.nature.com/naturecommunications 11
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Author contributionsB.T.P. designed and performed experiments, analysed data and co-wrote the manuscript.H.M.L.D. supervised the project and co-wrote the manuscript.
Additional informationAccession codes: The X-ray crystallographic coordinates for structure 24a have beendeposited at the Cambridge Crystallographic Data Centre (CCDC), under depositionnumber CCDC 955223. These data can be obtained free of charge from The CambridgeCrystallographic Data Centre viawww.ccdc.cam.ac.uk/data_request/cif.
Supplementary Information accompanies this paper at http://www.nature.com/naturecommunications
Competing financial interests: The authors declare no competing financial interests.
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How to cite this article: Parr, B. T. and Davies, H. M. L. Highly stereoselective synthesisof cyclopentanes bearing four stereocentres by a rhodium carbene-initiated dominosequence. Nat. Commun. 5:4455 doi: 10.1038/ncomms5455 (2014).
ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms5455
12 NATURE COMMUNICATIONS | 5:4455 | DOI: 10.1038/ncomms5455 | www.nature.com/naturecommunications
& 2014 Macmillan Publishers Limited. All rights reserved.
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